Magical power of transition metals: Past, present, and future. Orha, L. Beilstein J. Bhattacharjya, A. Cherney, A.
Pd-catalyzed Fukuyama cross-coupling of secondary organozinc reagents for the direct synthesis of unsymmetrical ketones. Tetrahedron 70 , — Hooshmand, S. Recent advances in the Suzuki-Miyaura cross-coupling reaction using efficient catalysts in eco-friendly media.
Duan, L. Activation of aryl chlorides in water under phase-transfer agent-free and ligand-free Suzuki coupling by heterogeneous palladium supported on hybrid mesoporous carbon. Veisi, H. Tamoradi, T. Pd Nanoparticle fabricated tetrahydroharmancarboxylic acid analog immobilized magnetic nanoparticle catalyzed fast and expedient C-C cross coupling Suzuki and Stille reactions and C—S coupling towards aryl thioethers.
Select 4 , — CAS Google Scholar. Hong, K. Palladium nanoparticles on assorted nanostructured supports: Applications for Suzuki, Heck, and Sonogashira cross-coupling reactions. ACS Appl. Nano Mater. Magnetic lignosulfonate-supported Pd complex: Renewable resources-derived catalyst for aqueous Suzuki—Miyaura reaction. Lazaro, I. Sustainable carbon—carbon bond formation catalyzed by new oxamate-containing palladium II complexes in ionic liquids.
Liu, Q. Ghiaci, M. Preparation, characterization and application of silica-supported palladium complex as a new and heterogeneous catalyst for Suzuki and Sonogashira reactions. Pd complexes based on phosphine-linked cyclophosphazenes: Synthesis, characterization and application in Suzuki coupling reactions. Shakil Hussain, S. Palladium—bis oxazoline complexes with inherent chirality: Synthesis, crystal structures and applications in Suzuki Heck and Sonogashira coupling reactions. Polyhedron 70 , 39—46 Sobhani, S.
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Abstract In recent days, nanohybrid metal organic frameworks MOF have been considered as next generation catalysts due to their unique features like large surface to volume ratio, tailorable geometry, uniform pore sizes and homogeneous distribution of active sites.
Introduction In the recent past, scientists have witnessed unprecedented progress in catalysis, particularly after the inception and involvement of designed and engineered nanomaterials, in view of economic and environmental reasons 1 , 2 , 3.
Figure 1. Full size image. Experimental Preparation of UiObiguanidine UiObiguanidine is synthesized as our previous report Figure 2. Figure 3. Figure 4. Figure 5. Figure 6.
Figure 7. Full size table. Figure 8. Table 3 Screening of solvent. Table 4 Screening of base. Table 5 Variation of catalyst load. Table 6 Variation of temperature. Figure 9. Figure Table 8 Catalytic Comparison in the reaction between phenyl boronic acid and iodobenzene. Conclusion In summary, we introduce a biguanidine modified Zr-UiO metal organic framework with Pd NPs being decorated over its surface. References 1. Google Scholar Article Google Scholar CAS Google Scholar View author publications.
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Polym Chem , , — Biomacromolecules , , — J Organomet Chem , , Dalton Trans , , — J Mater Chem C , , 9: — Polym Chem , , 5: — Polym Chem , , 1: — Prog Mater Sci , , — Science , , — Nature , , 31— Adv Funct Mater , , J Mater Chem C, , 8: — Chem Eng J , , Nat Commun , , 9: Chem , , 5: — Adv Mater , , — Inorg Chem , , — OuYang J, Crassous J.
Coord Chem Rev , , — PubMed Google Scholar. Light Sci Appl , , Mater Chem Front , , 2: — Adv Opt Mater , , Acc Chem Res , , 2— Chakraborty I, Pradeep T. Nat Chem , , 9: — Nat Commun , , — J Phys Chem B , , — Chem Rev , , 1— Coord Chem Rev , , Sci Adv , , 6: eaay ACS Cent Sci , , 6: — Adv Sci , , 7: Nano Res , , — Nat Chem , , — Small , , Small Methods , , 2: Appl Catal B-Environ , , — Nat Mater , , — Nat Commun , , 4: Mater Horiz , , 5: — ACS Nano , , 7: — Nanoscale Adv , , 1: — J Mater Chem C , , 7: — Nat Rev Mater , , 5: — Nano Lett , , — Chem Sci , , 9: — Nat Commun , ,
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